Efficient Optimization-Based Trajectory Planning for Unmanned Systems in Confined Environments
Journal article, 2024

This research addresses the increasing demand for advanced navigation systems capable of operating within confined surroundings. A significant challenge in this field is developing an efficient planning framework that can generalize across various types of collision avoidance missions. Utilizing numerical optimal control techniques, this study proposes a unified optimization-based planning framework to meet these demands. We focus on handling two collision avoidance problems, i.e., the object not colliding with obstacles and not colliding with boundaries of the constrained region. The object or obstacle is denoted as a union of convex polytopes and ellipsoids, and the constrained region is denoted as an intersection of such convex sets. Using these representations, collision avoidance can be approached by formulating explicit constraints that separate two convex sets, or ensure that a convex set is contained in another convex set, referred to as separating constraints and containing constraints, respectively. We propose to use the hyperplane separation theorem to formulate differentiable separating constraints, and utilize the S-procedure and geometrical methods to formulate smooth containing constraints. We state that compared to the state of the art, the proposed formulations allow a considerable reduction in nonlinear program size and geometry-based initialization in auxiliary variables used to formulate collision avoidance constraints. Finally, the efficacy of the proposed unified planning framework is evaluated in two contexts, autonomous parking in tractor-trailer vehicles and overtaking on curved lanes. The results in both cases exhibit an improved computational performance compared to existing methods.

nonlinear optimization

Faces

Shape

trajectory planning

Collision avoidance

hyperplane separation theorem

Ellipsoids

S-procedure

Fans

efficient collision avoidance

Navigation

Optimization-based planning

Planning

Author

Jiayu Fan

Zhejiang University

Nikolce Murgovski

Chalmers, Electrical Engineering, Systems and control

Jun Liang

Zhejiang University

IEEE Transactions on Intelligent Transportation Systems

1524-9050 (ISSN) 1558-0016 (eISSN)

Vol. 25 11 18547-18560

Subject Categories

Robotics

Control Engineering

Computer Science

DOI

10.1109/TITS.2024.3436045

More information

Latest update

11/23/2024